Thermoplastic Product and Method for the Production of a Composite Product

ABSTRACT

A composite thermoplastic product includes a first polar engineering thermoplastic cohesively bonded to a second thermoplastic. The first thermoplastic can contain a polar thermoplastic polymer cohesively bonded to the second thermoplastic. The second thermoplastic can contain a styrene-based thermoplastic elastomer and a polyolefin. Methods for the production of the composite product include methods for forming an adhesive bond between polar engineering thermoplastics such as ABS, ABS/PC, PC or PMMA and non-polar thermoplastic elastomers containing styrene elastomers, such as SEBS or SEPS, combined with a polyolefin polymer.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of International PCT ApplicationPCT/EP2007/006874, filed Aug. 3, 2007, which claims the benefit ofGerman patent applications DE 10 2006 037 534.3, filed Aug. 10, 2006,and DE 10 2006 037 535.1, filed August 10, 2006. The contents of PCTApplication PCT/EP2007/006874 and German patent applications DE10 2006037 534.3 and DE 10 2006 037 535.1 are incorporated herein by referencein their entirety.

TECHNICAL FIELD

This disclosure relates to thermoplastic products and methods forproducing composite products.

BACKGROUND

Cohesive bonding with engineering thermoplastics such as ABS(acrylonitrile butadiene styrene copolymers), ABS/PC (acrylonitrilebutadiene styrene copolymers/polycarbonate), PC (polycarbonate) and PMMA(polymethylmethacrylate) may be obtained by combining SEBS(polystyrene-poly(ethylene/butylene)-polystyrene) with polarthermoplastic elastomers such as TPE-E (thermoplastic polyesterelastomers) or TPU (thermoplastic polyurethanes). Products of such kindare described for example in U.S. Pat. No. 5,149,589.

Thermoplastic elastomers containing SEBS/PP (polystyrenepoly(ethylene/butylene) polystyrene/polypropylene) can exhibitoutstanding cohesive bonding with polyolefinic substances such aspolypropylene or a polyolefin. Even transparent materials with thiscomposition are known. For example, Volume 1/2005, pages 34-36 ofKunststoffe includes an account to the effect that adhesion to PC, PMMAand MABS (methylmethacrylate acrylonitrile/butadiene styrene copolymers)is possible with materials containing S-SB-S (partially unsaturatedstyrene/butadiene block copolymer), which is sold under the brand nameStyroflex®. This material has a hardness of 85 Shore A. This isconsidered to be too hard for many insulation applications, and itcannot be used in many outdoor applications because of the presence ofdouble bonds.

Modifying SEBS with TPE-E or TPU and compatibilization usingacid-modified SEBS or modified PP (polypropylene) can be expensive anddifficult. In certain components, the multi-phase construction canresult in delamination in the area of the sprue gate. The materials mustoften be dried beforehand because they are blended with polarthermoplastic elastomers such as TPE-E or TPU that are prone tohydrolyzing. In addition, adhesion-modified materials according to therelated art cannot be used as insulating materials at temperatures above70° C.

Two fundamentally different methods are used in the related art toproduce ornamental, partially electroplated parts or multicomponentparts with ornamental electroplating. In the first method, the hardplastic parts are injected, electroplated and extrusion coated with TPE.This method is used to manufacture side panels for electric shavers, forexample. The disadvantage of this method is that it is expensive,because the tools and the process in general require extremely closetolerances. Moreover, the reject ratio associated with this method isnot insignificant. Moreover, electroplating is a clearance-based processin which layer thicknesses are determined among other factors by theposition on the electroplating jig. The variations in layer thicknessesinherent in the process must be controlled with sophisticated processguidance and monitoring systems. It is also considered a disadvantagethat manual intervention is required in a high proportion of the variousprocess steps. It is also disadvantageous that only a positive lockingbond is created between the electroplated part and the soft plasticpart, which means that no impermeability is created between the parts.If such a seal is necessary, it can only be produced with an even morecomplex equipment configuration and additional sealing elements. Thesecond method takes into account a more complex part design, so that thenumber of process steps, as described in the first method, may bereduced and the equipment design may be simplified. Accordingly, theparts must be provided with a complicated sealing strip made from anon-electroplated plastic. This is necessary to prevent theelectroplated layer from being damaged when the tool is closed. Thedisadvantage in this case is that a three-component injection moldedpart is needed, which entails greater investment.

There remains a need for methods of producing transparent polymercompounds with excellent cohesive bonding to amorphous engineeringthermoplastics and good weathering properties, as well as a Shorehardness values below 70 Shore A. In addition, there remains a need formethods to electroplate hard/soft composite products selectively whenstandard commercial thermoplastic elastomers (TPEs) constitute the softcomponent.

SUMMARY

Thermoplastic products are provided that include a first polarengineering thermoplastic cohesively bonded to a second thermoplasticcontaining a styrene-based thermoplastic elastomer and a polyolefin.Surprisingly, the first polar engineering thermoplastic can becohesively bonded to the second thermoplastic, for example by using themethods disclosed herein. As a result, an adhesive bond can be formedbetween polar engineering thermoplastics such as ABS, ABS/PC, PC or PMMAand non-polar thermoplastic elastomers containing styrene elastomerscombined with polyolefins. The thermoplastic products can include acomposite comprising (or consisting essentially of) a firstthermoplastic comprising (or consisting essentially of) a polarengineering thermoplastic such as ABS, ABS/PC and/or PMMA cohesivelybonded to a second thermoplastic comprising (or consisting essentiallyof) a polyolefin and a styrene-based thermoplastic elastomer such aspolystyrene poly(ethylene/propylene) polystyrene (SEPS) and/orpolystyrene poly(ethylene/butylene) polystyrene (SEBS).

Methods for producing a composite product are also provided. The methodscan include providing an injection mold and injection molding thecomposite product in the injection mold. The composite product caninclude a hard plastic part and a soft plastic part. The hard plasticpart can comprise (or consist essentially of) a polar amorphousengineering thermoplastic material (e.g., ABS, ABS/PC, PMMA). The softplastic part can comprise (or consist essentially of) a styrene-basedelastomer (e.g., SEBS or SEPS) and a polyolefin. The styrene-basedelastomer can have a crystalline portion of not more than 20% by weightof the elastomer. For example, the soft plastic part can comprise (orconsist essentially of) a polystyrene poly(ethylene/butylene)polystyrene that has a side chain fraction of more than 60%.

The method can further include one or more of the following: selectivelyelectroplating the composite product, overmolding the hard plastic partwith a thermoplastic made from the styrene-based elastomer and thepolyolefin, performing one or more reject inspection(s) (e.g., after theinjection and the selective electroplating), incorporating metalliceffect spangles in the composite product, hardening the compositeproduct and/or applying printing to the composite product.

DESCRIPTION OF DRAWINGS

FIG. 1 shows a toothbrush 1 manufactured as a composite product.

FIG. 2 shows a plan view of an ornamental composite product 6.

FIG. 3 shows a side view of ornamental composite product 6 of FIG. 2.

FIG. 4 shows an inclined view of a screw cap or lid 8.

FIG. 5 shows a side view of the screw cap or lid 8 of FIG. 4.

FIG. 6 shows side view of a switch or display 10.

DETAILED DESCRIPTION

A thermoplastic product is provided that includes a first polarengineering thermoplastic with cohesive bonding to a secondthermoplastic, which includes a styrene-based thermoplastic elastomerand a polyolefin. In some examples of the product, the crystallineportion of the styrene-based thermoplastic elastomer can constitute notmore than 20% by weight of the elastomer. The thermoplastic product caninclude an adhesive bond between polar engineering thermoplastics suchas ABS, ABS/PC, PC or PMMA and non-polar thermoplastic elastomerscontaining styrene elastomers combined with polyolefins.

A low crystalline fraction (e.g., no more than 20%) in the styrene-basedthermoplastic elastomer may be achieved by selecting appropriate,commercially available styrene elastomers of the SEBS group with a highside chain portion (e.g., more than 60%). Suitable commercial productsare for example Kraton® MD 6932, Kraton® MD 6924 or Kraton® RP 6945.Another option in this context consists in the selection of SEPS(polystyrene poly(ethylene/propylene) polystyrene), which also has anamorphous soft segment due to its molecular structure. Such products aresold commercially under the trade name Septon®. Moreover,crystallization of the soft segment of standard SEBS types such asKraton® G1651, or of SEEPS (polystyrenepoly(ethylene/ethylene/propylene) polystyrene), which are sold forexample under the name Septon® 4055, may be prevented by α-olefins,which are sold for example under the trade name Engage®, or by atacticpolypropylenes, which are sold for example under the trade name Rextac®.Other polyolefins selected from the group of homo- or copolymers,particularly PP (polypropylene) and PE (polyethylene) may be added tothe second thermoplastic in an amount of up to 70%. Additionally, apolyolefin modified with maleic acid anhydride, or special styreneelastomers, such as those sold under the trade names Orevac® CA 100 orKraton® FG 1901, may be added to the second thermoplastic. Softenersfrom the group of paraffinic or engineering oils may also be added inquantities of up to 60% by weight of the second thermoplastic. Thesecond thermoplastic may contain usual commercial fillers and/orreinforcing agents such as calcium carbonate, talc, barium sulphate,metal oxides, hydroxides or silicic acid in quantities of up to 80% byweight. Standard additives such as antioxidants, light stabilisers,lubricants or colorants may also be added.

The thermoplastic product can be characterized in that it includes afirst polar engineering thermoplastic with cohesive bonding to a secondthermoplastic, which includes a styrene-based thermoplastic elastomerand a polyolefin. The crystalline portion of the styrene-basedthermoplastic elastomer can constitute not more than 20% by weight ofthe elastomer. For example, the second thermoplastic can include one ormore of the following: (a) a SEBS in which the side chain represents afraction of more than 60%, (b) a SEPS with amorphous soft segments, (c)atactic polypropylene and/or α-olefins, (d) a polyolefin selected fromthe group consisting of homopolymers or copolymers (e.g., polyolefin canbe a homopolymer or copolymer of polyethylene or polypropylene), (e) anacid-modified polypropylene or an acid-modified styrene-basedthermoplastic elastomer, (f) softeners from the group consisting ofparaffinic or engineering oils in quantities of up 60% by weight of thesecond thermoplastic, (g) fillers and/or reinforcing agents, (h) calciumcarbonate, talc, barium sulphate, metal oxides, metal hydroxides orsilicic acid (e.g., in quantities up to 80% by weight of the secondthermoplastic) and (i) antioxidants, light stabilizers, lubricants orcoloring agents. The first thermoplastic can be an amorphousthermoplastic. The thermoplastic product can be characterized in that itis able to be injection molded, extruded or calendered.

This disclosure further relates methods for producing a compositeproduct. These methods can include injection molding a compositeproduct, and selective electroplating. By following methods describedherein, it is possible to create an adhesive bond between polarengineering thermoplastics such as ABS, ABS/PC, PC or PMMA and non-polarthermoplastic elastomers containing styrene elastomers combined withpolyolefins. For example, a method of producing a composite product caninclude selective electroplating from a hard plastic part and a softplastic part. A thermoplastic including a styrene-based elastomer and apolyolefin can be used to produce the soft plastic part. The method caninclude the steps of a) creating an injection mold for the compositeproduct, b) injecting the composite product, and c) selectivelyelectroplating the composite product. The method can also include rejectinspection steps carried out as additional process steps (e.g., afterthe injection and electroplating). The thermoplastic made fromstyrene-based elastomer and polyolefin can be used to produce the softplastic part.

In order to illustrate particular advantages of one method disclosedherein (e.g., Method 1 in Table 1 below), Method 1 is contrasted with adescription of another method (e.g., Method 2 in Table 1 below) withreference to the Table 1 below. Method 2 includes separate steps forcreating an injection mold for the hard plastic part and the softplastic part, instead of injection molding of a composite product (e.g.,as shown in Method 1).

TABLE 1 Method 1 Method 2 Creation of an injection mold Creation of aninjection mold for the for the composite product hard plastic part ↓ ↓Creation of an injection mold for the soft plastic part ↓ Injectionmolding of the Injection molding of the hard plastic composite productpart ↓ ↓ Reject inspection of the Reject inspection of the hard plasticcomposite product part ↓ ↓ Selective electroplating Electroplating ofthe hard plastic of the composite product part ↓ ↓ Reject inspection ofthe Reject inspection of the electroplated electroplated compositeproduct hard plastic part ↓ Insertion of the had plastic part accordingto cavity ↓ Injection molding of the soft plastic part ↓ Rejectinspection of the electroplated composite product

Referring to Table 1, apart from being several steps shorter than Method2, Method 1 has a further advantage over Method 2 in that the individualparts are not joined mechanically by cohesive bonding. This may alsoinvolve several hard plastic parts on the one hand and several softplastic parts on the other. With the use of the thermoplastic made fromstyrene-based elastomer and polyolefin, including Method 1 in Table 1,it is possible to electroplate the hard plastic part or parts becausethe thermoplastic is resistant to chromic-sulphuric acid. The compositeproduct may thus be manufactured and subsequently electroplated in aprocess that is very similar to the standard process.

The styrene-based thermoplastic elastomer (e.g., in the soft plasticpart of the composite) can be a polystyrene poly(ethylene/butylene)polystyrene (SEBS) that has a side chain fraction of more than 60%. Thisresults in a high amorphous fraction in the soft segment of thethermoplastic. Thermoplastics of such kind are sold under the tradenames Kraton® MD 6932, Kraton® RP 6924 or Septon® 2063 in combinationwith polypropylene. The second thermoplastic (e.g., the soft plasticpart of the composite) can also include a polyolefin. Normal softenersand fillers may be added to the second thermoplastic for production ofthe soft plastic part. The crystalline fraction of the thermoplastic ofstyrene-based elastomer used to produce the soft plastic part preferablymakes up no more than 20% by weight of the elastomer.

A polar amorphous engineering thermoplastic is preferably used as thehard plastic part of the composite. Of these, an acrylonitrile butadienestyrene copolymer (ABS) or ABS blend is particularly suitable. Theselend themselves well to electroplating. The best electroplating methodsfor ABS are the classic methods with chromic-sulphuric acid, and alsoionogenic as well as colloidal methods. Concerning plasticmetallization, the reader is referred to the HandbuchKunststoff-Metallisierung [Plastic Metallization Manual], Leuze Verlag,Saulgau/Württemberg, 1991.

Methods for producing a composite product with selective electroplatingfrom a hard plastic part and a soft plastic part can be characterized inthat a thermoplastic including a styrene-based elastomer and apolyolefin is used to produce the soft plastic part. The methods canalso include one or more of the following: (a) creating an injectionmold for the composite product, (b) injecting the composite product and(c) selectively electroplating the composite product. The methods can becharacterized in that one or more reject inspection(s) can be carriedout as additional process steps after the injection and electroplating.The hard plastic part can be over-molded with the thermoplastic madefrom styrene-based elastomer and polyolefin. The methods can further becharacterized by and/or comprise one or more of the following: (1) thethermoplastic is made from styrene-based elastomer and polyolefin andcan be colored with metallic effect spangles, (2) printing is applied tothe hard plastic part, (3) a polar amorphous engineering thermoplasticis used as the hard plastic, (4) an acrylonitrile butadiene styrenecopolymer is used as the hard plastic, (5) the thermoplastic made fromstyrene-based elastomer has a crystalline portion of not more than 20%by weight of the elastomer, and (5) a polystyrenepoly(ethylene/butylene) polystyrene that has a side chain fraction ofmore than 60% is used to produce the soft plastic part. The hard plasticpart can be overmolded in the thermoplastic made from styrene-basedelastomer and polyolefin. Printing can be applied to the hard plasticpart. The transparency of the hard and soft plastic parts can also becombined with special light effects to offer a range of possibilitiesfor designers.

Yet another preferred method is one that is characterized in that thethermoplastic of styrene-based elastomer and polyolefin is colored withmetal effect spangles. Particularly striking effects may be achieved bycoloring the hard plastic part, which is capable of being electroplated,and overmolding it with the soft plastic part that is not electroplated.The substrate color can then only be visible in the area covered by thetransparent soft material. Special effects may also be created if thetransparent soft plastic part is colored with metallic effect spanglesand has a colored background to give the effect of depth, or a part ofthe area to be overmolded is decorated, for example by printing. Withthis process, it is also possible to keep areas of the molded part'ssurface free of metallic coating by designing the geometry of the softplastic part to shield the surface line in the electroplating bath,thereby creating even more color effects.

Areas of application for the composite products manufactured with themethods described herein include, for example, shavers, plating jigprotectors, packaging or small bottles.

EXAMPLES

In the following text, examples of thermoplastic products will beexplained in greater detail with reference to a number of examples.

Example 1

A polymer compound is produced in the normal way from 30.3% by weightSEBS having a side chain fraction of more than 60% (Kraton® RP 6924),24.2% by weight paraffinic white oil (Primol 382), 3.0% by weighthomopolypropylene (Borealis HD 120 MO), 18.2% by weight copolymerizedpolypropylene (Hifax® CA 60A) and 24.3% by weight CaO3 (Calcilit 6G).

Example 2

A polymer compound is produced in the normal way from 84.7% by weightSEBS having a side chain fraction of more than 60% (Kraton® MD 6932) and15.3% by weight PPMAH (polypropylene maleic acid anhydride) (Orevac® CA100).

Example 3

A polymer compound is produced in the normal way from 66.7% by weightSEPS (Septon® 2063), 16.7% by weight copolymerized polypropylene (Hifax®CA 60A) and 16.6% by weight atactic polypropylene (Rextac® APAO 3585).

Comparison Example 1

A polymer compound is produced in the normal way from 19.2% by weightSEBS (Kraton® G1654), 5.8% by weight SEBS-MAH (Kraton® FG 1901), 23.1%by weight paraffinic white oil (Primol 382), 32.7% by weight TPE-E(Hytrel 4068) and 19.2% by weight CaCO3 (Calcilit 6G).

Comparison Example 2

One hundred (100) percent S-SB-S (Styroflex® 2G 66) is used. The polymercompounds of the examples and comparison examples are homogenised on atwin screws compounding extruder (Berstorff ZE 50 A), and two-componentcomposite body is produced on the Klockner-Ferromatik F 110 injectionmolding machine. For this, the surfaces of ABS discs (Polylac 717) withdimensions of 150 mm·100 mm·2 mm are overmolded with 2 mm of themixtures from the examples. The peeling forces for the mixtures from allexamples are then tested comparatively on 200 mm wide strips, with anpeel angle of 90° and test speeds of 100 mm/min on a Zwick 1445 tensilestrength test machine. The averages of the peeling forces are shown inTable 2, together with the hardness of the respective mixtures.

TABLE 2 Comparison Comparison Example 1 Example 2 Example 3 example 1example 2 Hardness 55 Shore A 55 Shore A 55 Shore A 56 Shore A 84 ShoreA Adhesion to 32 MPa 37 MPa 46 MPa 29 MPa 69 MPa ABS

The thermoplastic product can exhibit significantly strongermaterial-based cohesive bonding than corresponding products of therelated art. As a result, the thermoplastic product may be used, forexample, as a seal against aqueous media. The thermoplastic product canhave a further advantage over the related art in that it can also betransparent, thereby offering designers previously unknownpossibilities. Another important advantage of the thermoplastic productscan be that they provide good cohesive bonding even with Shorehardnesses of 50 Shore A and below.

Examples of the methods for producing a composite product with selectiveelectroplating and the advantages that have been described thereof willbe explained in greater detail in the following with reference to theFigures.

FIG. 1 shows a toothbrush 1 manufactured as a composite product inaccordance with Method 1 discussed with respect to Table 1. Toothbrush 1has a handle and a brush head. These two elements are connected by abrush neck. Together, they represent hard plastic part 3′. Hard plasticpart 3′ may be transparent to colored. The handle is encased withelectroplating layer 5′. The handle is separated visibly from the brushneck by soft plastic part 4′, which serves as an insulator. In atwo-component injection molded application, this lends the appearance ofthree components.

FIG. 2 shows a plan view of an ornamental composite product 6. Animprint or embossment 7 is applied to decorative product 6, which has acolored support as hard plastic part 3″. Imprint or embossment 7 areovermolded with transparent soft plastic part 4″. The area of hardplastic part 3″ that is not overmolded is covered by electroplatinglayer 5″.

FIG. 3 shows a side view of ornamental composite product 6 of FIG. 2.

FIG. 4 shows an inclined view of a screw cap or lid 8. In this case, anannular soft plastic part 4′″ encircles the screw cap or lid 8 roughlyin the middle thereof. Soft plastic part 4′″ is transparent to coloredand has an insulating effect. Hard plastic part 3′″ serves as the basematerial and is colored. Electroplating layer 5′″ is applied to hardplastic part 3′″, except in the area occupied by annular soft plasticpart 4′″. Screw cap or lid 8 is a two-component injection molded productthat has the appearance of a three-component item.

FIG. 5 shows a side view of the screw cap or lid 8 of FIG. 4. A thread 9is shown for the alternative.

FIG. 6 shows side view of a switch or display 10. In this case, hardplastic part 3″″ serves as the transparent support material. The middleof both the upper side and the lower side of this part is overmoldedwith transparent soft plastic part 4″″. The rest of the surface of hardplastic part 3″″ is covered with electroplating layer 5″″. A lightingmeans 2 is located below switch or display 10. The transparency of bothhard plastic part 3″″ and soft plastic part 4″″ thus enable particularlystriking optical effects to be created on the upper side of switch ordisplay 10.

1. A thermoplastic product, comprising: a first polar engineeringthermoplastic cohesively bonded to a second thermoplastic, the secondthermoplastic comprising a styrene-based thermoplastic elastomer and apolyolefin.
 2. The thermoplastic product of claim 1, wherein acrystalline portion of the styrene-based thermoplastic elastomerconstitutes not more than 20% by weight of the styrene-basedthermoplastic elastomer.
 3. The thermoplastic product of claim 1,wherein the first polar engineering thermoplastic comprises a materialselected from the group consisting of: ABS (acrylonitrile butadienestyrene copolymers), ABS/PC (acrylonitrile butadiene styrenecopolymers/polycarbonate), PC (polycarbonate) and PMMA(polymethylmethacrylate).
 4. The thermoplastic product of claim 1,wherein the second thermoplastic comprises a material selected from thegroup consisting of: SEBS and SEPS.
 5. The thermoplastic product ofclaim 1, wherein the second thermoplastic comprises a material selectedfrom the group consisting of: a SEBS in which the side chain representsa fraction of more than 60% and a SEPS with amorphous soft segments. 6.The thermoplastic product of claim 1, wherein the second thermoplasticcomprises a material selected from the group consisting of: anacid-modified polypropylene and an acid-modified styrene-basedthermoplastic elastomer.
 7. The thermoplastic product of claim 1,wherein the polyolefin comprises a polymer selected from the groupconsisting of: an atactic polypropylene and an α-olefin.
 8. Thethermoplastic product of claim 1, wherein the polyolefin comprises apolymer selected from the group consisting of: a homopolymer ofpolyethylene, a copolymer of polyethylene, a homopolymer ofpolypropylene and a copolymer of polypropylene.
 9. The thermoplasticproduct of claim 1, wherein the second thermoplastic is cohesivelybonded to the first polar engineering thermoplastic with peeling forceof at least about 32 MPa.
 10. The thermoplastic product of claim 1,further comprising an electroplating layer contacting the first polarengineering thermoplastic.
 11. The thermoplastic product of claim 1,wherein a. the first polar engineering thermoplastic comprises amaterial selected from the group consisting of: ABS (acrylonitrilebutadiene styrene copolymers), ABS/PC (acrylonitrile butadiene styrenecopolymers/polycarbonate), PC (polycarbonate) and PMMA(polymethylmethacrylate); b. the styrene-based thermoplastic elastomercomprises at least one material selected from the group consisting of: aSEBS in which the side chain represents a fraction of more than 60%, aSEPS with amorphous soft segments and an acid-modified styrene-basedthermoplastic elastomer; and the styrene-based thermoplastic elastomerhas a crystalline portion that constitutes not more than 20% by weightof the styrene-based thermoplastic elastomer; and c. the polyolefincomprises a polymer selected from the group consisting of: an atacticpolypropylene, an α-olefin and an acid-modified polypropylene; and d.the thermoplastic product further comprises a material selected from thegroup consisting of: calcium carbonate, talc, barium sulphate, metaloxides, metal hydroxides, and silicic acid.
 12. A method for producing acomposite product, the method comprising a. providing an injection mold,b. injection molding the composite product in the injection mold, thecomposite product including a hard plastic part and a soft plastic partcomprising a styrene-based elastomer and a polyolefin; and c.selectively electroplating the composite product.
 13. The method ofclaim 12, wherein injection molding the composite product includesinjection molding a polar amorphous engineering thermoplastic in thehard plastic part.
 14. The method of claim 12, wherein injection moldingthe composite product includes injection molding an acrylonitrilebutadiene styrene copolymer in the hard plastic part.
 15. The method ofclaim 12, wherein injection molding the composite product includesinjection molding a styrene-based elastomer having a crystalline portionof not more than 20% by weight of the elastomer in the soft plasticpart.
 16. The method of claim 12, wherein injection molding thecomposite product includes injection molding the soft plastic partcomprising a polystyrene poly(ethylene/butylene) polystyrene that has aside chain fraction of more than 60%.
 17. The method of claim 12,further comprising overmolding the hard plastic part with thethermoplastic made from the styrene-based elastomer and the polyolefin.18. The method of claim 12, further comprising performing a rejectinspection after the injection and the selective electroplating.
 19. Themethod of claim 12, further comprising one or more steps selected fromthe group consisting of: selectively electroplating a surface of thehard plastic part, incorporating metallic effect spangles in thecomposite product, and hardening the composite product and applyingprinting to the hardened composite product.
 20. The method of claim 12,wherein injection molding the composite product includes injectionmolding a polar amorphous engineering thermoplastic in the hard plasticpart and injection molding a styrene-based elastomer having acrystalline portion of not more than 20% by weight of the elastomer inthe soft plastic part; and the method further comprises: a. overmoldingthe hard plastic part with the styrene-based elastomer and thepolyolefin; b. performing a reject inspection after the injection andthe selective electroplating; c. hardening the composite product; and d.applying printing to the hardened composite product